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Life Sciences at ISOLDE Using PAC- spectroscopy

Life Sciences at ISOLDE Using PAC- spectroscopy. Tilman Butz Universität Leipzig, Germany. Outline Why Spectroscopy? Perturbed angular correlation (PAC) of γ -rays Why ISOLDE? Selected examples Advantages and limitations. Why Hyperfine Spectroscopy on Biomolecules?.

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Life Sciences at ISOLDE Using PAC- spectroscopy

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  1. Life Sciences at ISOLDE Using PAC-spectroscopy • Tilman Butz • Universität Leipzig, Germany • Outline • Why Spectroscopy? • Perturbed angular correlation • (PAC) of γ-rays • Why ISOLDE? • Selected examples • Advantages and limitations

  2. Why Hyperfine Spectroscopy on Biomolecules? Structural information is usually obtained by single crystal diffraction What to do if the biomolecules do not crystallize? What to do if only very small amounts of material are available? Sometimes internal dynamics renders entire domains „invisible“ by diffraction, e.g. in trypsinogen. Often internal dynamics is crucial for the function. Solution: Spectroscopy like EPR, Mössbauer, Perturbed Angular Correlation Requires isomorphous replacements with suitable isotopes

  3. Angular correlation of γ-rays: Angular correlation of γ-rays is a property of the nuclear decay: γ1 The distance from the center to the curve gives the probability of emission of γ2 in that direction 111Cd

  4. Perturbed angular correlation of γ-rays: The influence of extra-nuclear fields Oscillations in the angular correlation give ω1, ω2, and ω3 – a finger print of the local charge distribution 111Cd Hamilton Phys. Rev., 1940, 58:122, Brady and Deutsch Phys. Rev.1947, 72:870, Goertzel Phys. Rev., 1946, 70:897, Aeppli et al. Phys. Rev., 1951, 82, 550, Leipert et al. Nature, 1968, 220:907 Butz Z. Naturforsch.1996, 51A:396

  5. PAC in a nutshell W180W90 Calculate spectroscopic data based on putative structure Compare L. Hemmingson, Copenhagen

  6. Why ISOLDE? • Isomorphous replacement should be performed with isotopes which have isomeric states; otherwise, chemical transmutation can cause after-effects. • The additional requirement of a cascade with a sufficiently longlived intermediate state narrows down the number of suitable radioisotopes. • Suitable PAC-isotopes are e.g. 111mCd, 199mHg, 204mPb; all happen to be shortlived (about 1 hour) and have to be produced on-line. • Because of the large molecular weight of the biomolecules no-carrier added activity is required. • ISOLDE meets all these requirements !

  7. Protein-protein interactions Plastocyanin binding to photosystem 1 Cu-plastocyanin (wildtype) binds to PS1 Ag-plastocyanin binds to PS1, but Cd-plastocyanin does not. (111Ag decays to 111Cd) 111Ag mimicks Cu+ 111Cd mimicks Cu++ Note: The experiments were carried out without added sucrose. Danielsen et al. Biochemistry, 1999, 38:11531

  8. Metal ion binding site structure and dynamics Azurin (P. aeruginosa) and plastocyanin (spinach) Linewidth reveals internal motion in plastocyanin Bauer et al. JACS, 1997, 119:157, Tröger et al. Z. Naturforsch., 1996, 51A:431, Danielsen et al. Biochemistry, 1999, 38:11531,

  9. Metal ion binding site structure during catalysis (bovine Carboxypeptidase A) Bauer et al. Biochemistry,1997, 36:11514

  10. Results on Azurin with 111mCd and 199mHg Experiments performed at ISOLDE 111mCd 111mCd 111Ag 199mHg 111Ag Azurin a small electron transfer protein 199mHg W. Tröger and T. Butz, Hyp. Int. 129 (2001) 511.

  11. First results with 204mPbBr2 at ISOLDE Complication: I = 4  many spectral lines Sven Friedemann, Diploma Thesis, 2004, U. Leipzig Frank Heinrich, PhD thesis 2005, U. Leipzig

  12. First results with 204mPb Solution: Cross-Correlation compresses information into a spot Sven Friedemann. Diploma Thesis, 2004, U. Leipzig

  13. First results with 204mPb in Azurin probe Vzz (a.u.) h 111mCd 1.84 0.52 199mHg 6.21 0.70 204mPb 4.26 0.50 Similarh means rigid metal coordination solvent solvent + azurin azurin Result: incomplete isomorphous replacement Frank Heinrich, PhD Thesis, 2005, U. Leipzig

  14. Outlook: Freeze quench PAC spectroscopy Snap shots of structures evolving during enzyme catalyzed reactions (Future research planned by L. Hemmingsen, Copenhagen) Enzyme Substrate

  15. Advantages and limitations of PAC-spectroscopy • Advantages: • Metal ion binding site structure • and dynamics can be measured • Protein-protein and protein- • membrane interactions can be • measured • High sensitivity to structural • changes • Small amounts of sample needed • (in principle 1 pmol, but 100 nM • for 111mCd substituted proteins) • Different physical states • (crystals, solutions, in vivo...) • Mechanically stable, allowing for • stirring, flow, ... • Limitations: • PAC isotope must bind strongly to • the molecule of interest • Spectral parameters do not uniquely • determine structure • After effects can cause problems (in • particular for EC) • Production of PAC-isotopes

  16. Researchers involved • Copenhagen, Denmark • Rogert Bauer († 2004) • Lars Hemmingsen • Mikael Jensen • Lars Olsen • Eva Danielsen, Klara N. Sas • Morten J. Bjerrum • Jens Ulstrup & group • Henrik V. Scheller • University of Leipzig, Germany • Tilman Butz • Wolfgang Tröger • Frank Heinrich • Sven Friedemann • Saarland University, Gemany • Hans Werner Adolph • Michael Zeppezauer & group • Lund University, Sweden • Eila Cedergren-Zeppezauer • Ulf Ryde • University of Michigan, USA • Vincent L. Pecoraro & group • Göteborg University, Sweden • Örjan Hansson • Harvard Medical School, USA • David S. Auld

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